Title :
A Carrier-Transit-Delay-Based Nonquasi-Static MOSFET Model for Circuit Simulation and Its Application to Harmonic Distortion Analysis
Author :
Navarro, Dondee ; Takeda, Youichi ; Miyake, Masataka ; Nakayama, Noriaki ; Machida, Ken ; Ezaki, Tatsuya ; Mattausch, Hans Jürgen ; Miura-Mattausch, Mitiko
Author_Institution :
Graduate Sch. of Adv. Sci. of Matter, Hiroshima Univ.
Abstract :
In this paper, a compact model of nonquasi-static (NQS) carrier-transport effects in MOSFETs is reported, which takes into account the carrier-response delay to form the channel. The NQS model, as implemented in the surface-potential-based MOSFET Hiroshima University STARC IGFET model, is verified to predict the correct transient terminal currents and to achieve a stable circuit simulation. Simulation results show that the NQS model can even reduce the circuit simulation time in some cases due to the elimination of unphysical overshoot peaks normally calculated by a QS-model. An average additional computational cost of only 3% is demonstrated for common test circuits. Furthermore, harmonic distortion characteristics are investigated using the developed NQS model. While the distortion characteristics at low drain bias and low switching frequency are determined mainly by carrier mobility, distortion characteristics at high frequency are found to be strongly influenced by channel charging/discharging
Keywords :
MOSFET; carrier mobility; circuit simulation; delays; harmonic distortion; semiconductor device models; surface potential; carrier mobility; carrier transit delay; carrier-response delay; carrier-transport effects; channel charging; channel discharging; circuit simulation; compact model; distortion characteristics; harmonic distortion analysis; nonquasi-static MOSFET model; surface potential; switching frequency; Circuit simulation; Circuit testing; Computational efficiency; Computational modeling; Delay effects; Harmonic analysis; Harmonic distortion; MOSFET circuits; Predictive models; Switching frequency; Harmonic distortion (HD); Hiroshima University STARC IGFET model (HiSIM); nonquasi-static (NQS) effect; surface-potential-based MOSFET model;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2006.880827
